Temperature-regulating device



April 1.5, 1941. s. P. VAUGHN ET A1. 2,238,837

' TEMPERATURE-REGULATING DEVICE Filed May 9, 1940 2 Sheets-Sheet l illllllllllll l Il , 7 l; Ism

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INVENTO rrvoR/vfy.

April 15, 1941. s. P. VAUGHN ET AL 2,238,837

f TEMPERATURE-REGULATING DEVICE Filed )lay 9. 1940 .2 Sheets-Sheet 2 :di l

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INVENTORS.

rroRA/fx Patented Apr. 15, 1941 TEMPERATURE-REGULATING DEVICE Sidney P. Vaughn, Long Beach, and Wayne E.

Jenkins, Los Angeles, Calif., assigner: to Domestic Manufacturing Company, Inc., Los Angeles,

Calif., a corporation of CaliforniaV Application May 9, 1940, Seal No. 334,192

15 Claims.

This invention relates to thermostats and has to do more especially with water heater thermostats of the type wherein a Ifuel-control valve or electrical contact is automatically and abruptly opened and closed in response to temperature changes so as to maintain the hot water supply at a substantially constant temperature-that is to say, within a relatively narrow range.

Thermostatic devices in accordance with the present invention are of the snap-action disc variety wherein the valve or electrical contact is opened abruptly and, generally, also closed abruptly-being thus', in all instances, distinguished from thermostatic devices of the gradual operating type.

Qur invention also pertains more specifically to water heater thermostats of the type comprising a temperature-responsive element of the rod and tube variety--which element projects into the water heater tank and consists of a tube of thermally expansible metal, such as copper, and a co-axial rod of material such as Invar steel having an extremely low temperature co-efilcient of expansion. Temperature-responsive elements of the rod and tube type are highly satisfactory for use in domestic water heaters because they are dependable and relatively inexpensive to manufacture; but unlike some other types of elements which are not equally satisfactory in the above respects, the rod and tube type element is characterized in that it affords but an extremely small movement of the rod in response tothe ordinarily allowable range of temperature variation. More explicitly, in athermostat of the rod and tube type designed for use on domestic water heaters of common proportions and adjusted to limit the temperature variation to a range in the neighborhood of 15 to 20 degrees, the longitudinal movement of the rod is of the order of .002". Such a small movement is insufficient in practice to actuate a snap-action disc unless in one Way or another amplifying means are interposed between the temperature-responsive element and the snap-action disc or within the disc itself. The necessary amplification can be obtained as in Spencer U. S. Letters Patent No. 1,678,407 by applying the actuating forces to opposite faces of the disc along circumferential lines closely spaced radially whereby the disc itself is caused to function as a movement amplifying leverage system; or the amplification can be achieved by introducing a lever between the temperatureresponsive element and the snap-action disc, as shown in MerrickA U. S. Letters Patent No.

The arrangement of the aforementioned Spencer patent and, likewise, that of Grayson U. S. Letters Patent No. 1,699,468- which is simply another; form of the Spencer arrangement-is of the utmost mechanical simplicity but not entirely satisfactory for water heater service because if so designed and constructed as to operate within a narrow temperature range the disc will be inordinately strained whenever the thermostat may be subjected to very low temperatures; and it may thus be permanently injured or rendered inoperative.

In the device of the Merrick patent danger of injury to the disc when subjected to low temperatures is obviated by the provision of a resilient cup through which the actuating force is applied to the disc and which will yield to excessive forces-thus functioning to safeguard the disc against those forces. The Merrick thermostat, though functionally correct and reliable in operation, is somewhat costly to manufacture and, therefore, handicapped commercially in the highly competitive domestic water heater market.

One of the principal objects of our-present invention is to provide a water heater thermostat which is completely reliable in operation without being susceptible to injury when subjected to low temperatures and which can be manufactured at a cost which enables it to meet competition in the low price field.

Another important object is to provide a water heater thermostat wherein the temperature regulating knob or similar element is located at the front of the device Where it is completely visible and accessible, so that the housewife cannotonly operate it with ease but will know it is there and not be leftA in doubt as to its purpose and mode of operation.

Still another object is to provide a thermostatic valve of the abrupt action type in which a satisfactorlly large valve lift is obtained, thus providing an unconstricted passageway for gas through the valve.

A major feature of our invention resides in the combination with a free edge snap-action disc or annulus, of a plurality of resilient levers distributed around and extending radially from the axial center of the disc or annulus and serving as means for amplifying the small longitudinal movement of the rod of the temperature-responsive element and applying actuating force to the disc or annulus at or near the peripheral edge thereof-the aforesaid levers being preferably punched from a sheet of spring material such as stainless spring steel-there being preferably an interconnecting web between adjacent levers,

whichr web is integral with the levers and serves to locate and hold them in their proper relative positions. The assemblage of interconnected resilient levers here referred to forms what will be denominated a spiden and said spider is situated immediately adjacent the normally concave side of the disc or annulus and Vheld in concentric relation with the disc or annulus-being' gripped between a pair of fulcrum elements which serve to apply opposing forces to the levers so as toilol cause the outer ends of the levers to bear against the normally concave face of the disc or annulus with force suiicient to snap the same in response toa predetermined temperature condition. The levers forming the spider" are quite flexible,I but have enough rigidity, in the aggregate, to transmit adequate force to snap the disc; but the resiliency of the levers is such as to restrict the force within the limits of safety in event of the device being subjected to inordinately low temperatures--thus obviating possible injury to the disc or annulus, which might otherwise be expected to occur in extreme cold weather if the device happened to be so situated as to be'unprotected therefrom It is essential to the operation of any selfrestoring over center snap-action disc or annulus that the medium through which the actuating force is applied thereto be resilient to such an extent that it will yield during the initial application of force and be able instantly to recuperate and follow through, so to speak, when the disc or vannulus passes dead center. The ordinary rod and tube thermo-responsive element such as we employ has not the requisite yieldability to enable the Invar rod to follow through wherev the actuating forces are applied to the disc or annulus at its axial center and outer edge, respectively, or inner and outer peripheral edges, respectively, as the case may be. Hence, it is necessary to introduce the requisite yieldability at some convenient point between the expansible tube @and the disc or annulus. We do this most conveniently, compactly and economically in the preferred structures of the present invention by making the spider -of elastic sheet material.

'dit' ternative construction within the purview of our of; and (4) low manufacturing cost due to the 4cheapness of the spider punching and to simcation there are illustrated several embodiments of our invention.

Referring to the drawings:

Fig. 1 is a front elevational view of a thermostatic valve in accordance with what we consider the preferred construction;

Fig. 2 is a vertical section taken along the line 2-2 of Fig. 1, showing the internal mechanismthe fuel control valve being closed;

Fig. 3 is identical with Fig. 2 except that a portion of the temperature-responsive element has been broken oif and the fuel control valve shown open-the snap-action mechanism and associated parts being shown in their open-valve positions;

Fig. 4 is a face view of the spider taken along the line 4-4 of Fig. 2-showing also the frustro-conical snap-action annulus situated to the rear of the spider;

Fig. 5 is a perspective view of a frustro-conical snap-action annulus;

Fig. 6 is an enlarged detail, in section, comprising the annular snap-action disc, the spider and the two fulcrum elements, together with a portion of the Invar rod;

Fig. 7 is an enlarged view taken along the line l-l of Fig. 2, illustrating particularly the lever interconnecting the snap-action annulus with the stem of the fuel control valve;'

Fig. 8 is a sectional view of a thermostatic valve of modified design;

Fig. 9 is a sectional View illustrating still another modification;

Fig. 10 is a plan view of a spider of modified form; and

Fig. 11 is a sectional view illustrating an alinvention.

Modern domestic water heaters are most commonly of the gas-red storage type; although electrical heating is now being used also to a very considerable extent. A thermostatic control designed for use on a gas-fired automatic water heater of the storage type inevitably comprises a valve which isautomatically opened and closed to control the flow of gas to the main burnerthe valvebeing opened automatically when the water temperature has dropped to some predetermined value,-and, in turn, closed automatically when the temperature has thereafter risen to some higher predetermined value. Where the heatingl medium is electricity a switch is substituted in place'of theautomatic gas control valve. A closedlswitch allows current to flow to an electrical heating element and an open valve allows gas to ilow to a burner. Hence, a closed switch is analogous to aclosed valve. can always be substituted for the` other in any thermostatic device.

We are primarily interested in thermostatic valves for use on gas-fired water heaters and for that reason we have illustrated in the accompanying drawings only devices of that specific dial is graduated and appropriately marked asv shown. A stationary index 6, attached vtothe Manifestly, each enlargement body casting, registers with the dial graduations and serves to indicate the temperture of the water for which the device is adjusted. By rotating the knob and dial the householder can raise and lower the average temperature of the water in the tank to suit his momentary personal desires. The gas inlet and outlet connections are shown in Fig. 1 and marked accordingly. Other parts shown in Fig. 1 but unrelated to the present invention and not essential thereto will not be described. Provision of the dial 4 and knob 5 at the front of the device where it is completely visible, and the mechanical arrangement which makes this economically practicable constitutes an important feature.

The body casting 2 is provided with an external tapered thread at 1 by which it is screwed into a flange 8 forming a part of the water heater tank.

The temperature-responsive element, shown projecting into the tank, is of the conventional rod and tube type and comprises a metal tube 8, usually copper, one end of which is screwed into the body casting at I0. and a rod II of Invar steel or other material having a low temperature co-'efiicient of expansion. The free extremity of tube 8 is internally threaded to receive a plug I2 which is, in turn, provided with a left-hand internal thread at I3 to engage the correspondingly threaded end of rod II. Knob is attached to the other extremity of rod by means of a setscrew I4, and the rod is thus rotatable with the knob. Upon rotating the knob and dial, rod moves longitudinally by virtue of thread Il and, as will later appear, this manually accomplished longitudinal movement of the rod serves adjustably to vary the average temperature of the water in conformity with the householders desires. As a part of the manufacturing procedure the device is adjustedyto close the valve at some known temperature such as 140 degrees-the element being immersed in water at that temperature until the valve snaps closed. The dial is then turned, independently of rod I I, to bring thecorresponding temperature marking into registration with the index and setscrew I4 is thereupon tightened.

The automatic fuel control valve is shown in Figs. 2 and 3 and identified by reference nu,

meral I5. The valve is of the poppet type and has a stem |5a which is ,slidably supported in a. bore I6 in the body casting. A coil spring I1 bears against the Iback of valve I4 tending continously to close the valve and hold it closed. A cap I8 threaded into the body casting provides access to the valve and functions as an abutment forspring Il. Valve stem |5a has an |5b forming a shoulder against which bears the forked lower end of a, valveoperating lever I9 (see Fig. 7) which is fulcrumed on a pin 20. Lever I9 serves to open valve I5 under control of the snap-action mechanism which will now be described. It will be observed that the upper arm of lever I9 is much shorter than its lower arm. Hence, it will be obvious that lever I9 imparts an amplified movement to the valve, affording a substantially greater lift than could conveniently be achieved if the valve were directly actuated by the snap-action disc or annulus.

The snap-action mechanism by means of which the gradual longitudinal movements of rod are converted into abrupt movements for actuation of lever I9 and, in turn, valve I5, comprises a spring sheet metal disc or annulus 2|, a

"spider 22, a combined hub and fulcrum member 23, and a. stationary fulcrum member 24. The combined hub and fulcrum member 231s secured to rod Il -by means of a pin 25, and it moves with the rod. Member 23 performs two distinct functions. First, it serves as a hub on which the annulus 2| is loosely supported and centeredbeing formed with a shoulder 23a which bears against the normally convex face of the annulus along the edge of the axial opening. Secondly, itl serves as a fulcrum member and pusher element-being formed with an integral annular protuberance 23h which is designed to function as one of the two fulcrums for the amplifying levers constituting the spider 22. The

latterlis shown to best advantage in Fig. 4. It

is a sheet metal punching made, preferably, of stainless spring steel and comprises six resilient lever arms marked 22a to 22j, inclusive, all converging at the center in a web which serves as a medium for holding the levers in place. The six resilient lever arms extend radially from the axial center of the annulus 2| and rodl and their several outer ends bear against the normally concave face of the annulus at or near the I crums 23h and 24a. Figs. 2 and 6 illustrate the snap-action mechanism in its normal position or condition-that is to say, those flgures illustrate the condition which obtains when no pressure or insufficient pressure is being exerted by rod II to snap the annulus 2|being due to the fact that the water in the tank is hot and the copper tube 9 expanded lengthwise and the rod II and member 23 are disposed at the right hand end of their travel as viewed in Fig. 2.

A metal plug 26 threaded into the body casting serves as a bearing for rod II and as a closure member. It is recessed to receive a resilient packing washer 21 and retaining washer 28. 'I'he joint is thus packed to prevent escape of gas.

In snapping, the peripheral vedge of the annulus moves in such manner as to rotate the lever I9 about its fulcrum 2li-causing the fuel control valve abruptly to be lifted off its seat. The lift of the valve is substantially greater than the movement of the peripheral edge of annulus 2| because fulcrum 20 is so positioned that the lower arm of lever I9 is much longer' than the upper arm thereof.

We have included in the structure of Figs. 1 to '7, inclusive, a snap-action element in the form of a dished frustro-conical annulus 2|which is shown in perspective in Fig. 5. That particular form of over` center snap-action element is not essential to the operativeness of our device. We could substitute an annulus of curvilinear crosssection or a disc of curvilinear cross-section with or without an axial opening; but we find it advantageous to employ a frustro-conical annulus because, according to our experience. the frustroconical annulus affords a greater peripheral movement than -is obtainable with one of curvilinear cross-section and equal diameter. The frustro-conical annulus 2|.is made in accordance with the teachings of Vaughn, U. S. Letters Patent No. 1,988,345. Inl this speclilcation we frequently use the term disc conjointly or alternatively with annu1us" in reference .to element 2| and other similar elements. An annulus is simply a 'disc with an axial opening and we use the term disc as embracing annulus" within its scope. It will later be shown, with reference to Fig. 9, how a device in accordance with this invention can be-made with a snap-action disc having no axial .opening and, thereforeLnot an annulus.

The mode of operation of the above-described device is as follows: Assuming the water in the tank to have acquired the predetermined maximum temperature at which the control valve is adjusted to close, the copper tube 9 will have expanded longitudinally and rod Il, which expands but little, will have occupied the position in which it is depicted Yin Figs. 2 and 6. The two annular fulcrumsA 23h and 24a are therefore separated to a maximum extent axially and little or no pressure is exerted by lever arms 22a to 22j against the annulus 2|. Hence, the annulusretains its normal form (Figs. 2 and 6) and the fuel control valve I5 is closedthe main burner llame being, in consequence, extinguished. Since there is no llame to maintain the temperature, the water will cool and as its temperatures decreasesv the copper tube 9 Will contract and the Invar rod Il will move to the left, as viewed in Figs. 2 and 6. The movement of the rod` is, as previously stated, of a magnitude of about .002". Contraction of the copper tube gives rise to a large force which is transmitted to rod and thence to member 23, which latter is moved with the rod toward the stationary fulcrum member 24. Resilient lever arms 22a to 22f, inclusive, are, consequently, rotated about the two annular fulcrums so that their free outer ends push against the annulus 2|. spacing of the two annular fulcrums 23h and 24a being small Vcompared to the length of the free arm of each lever 22a to 22j, inclusive, it will be evident that the movement capable of being imparted to vthe free outer ends of said arms is comparatively large. The step-up levervthe resilient lever arms until the pressure exerted against the `annulus has reached the critical value-a magnitude sufllcient to cause the annulus suddenly to ysnap over dead center. The

vsnapping of the annulus occurs very abruptly and, as a result, the fuel control valve is opened abruptly and the main burner re-lighted.

When annulus 2| snaps' over dead center to `the abnormal form depicted in Fig. 3, resilient ""lever arms 22a to f, inclusive, follow through and continue to exert pressure on the annulus. The

The radial latter pressure is, of course, less than that which is necessary .to snap the annulus but considerably more than what is requiredto prevent the annulus from restoring itself to normal. The residual force of ilexure inthe lever armswill continue to retain the annulus in its abnormal form until the force applied to the resilient levers 22a to .f by the two fulcrum members 23 and 24 has been relieved to a predetermined extent by the expansion of copper tube S-due to the rising temperature of the water. Closure of the control valve will, of course, follow upon the annulus 2| returning .to normal form--which voccurs abruptly when the maximum predetermined water temperature is again reached.

Manifestly, annulus 2| could be pushed over dead center if levers 22a to f were rigid instead of resilient, but unless there is resiliency in the levers or somewhere in the actuating system there can be no snap action of the annulus. To obtain snap action the actuating force must be applied to the disc or annulus through a yieldable medium which is capable of following through the instant the disc lor annulus yields to the applied pressure. Making the "spider 22 of spring sheet material provides. the essential yieldability in a way whichv is extremely economical and compact. The space requirements are reduced to a minimum and likewise the cost of parts. 4

Spider 22 has an axial opening which fits rod and by which it is accurately centered. Members 23 and 24' vare both centered onfrod Il, wherefore the two annular fulcrums 23h and 24a are perfectly concentric;' and the annulus 2| also ls perfectly concentric with the rod because lt is mounted on a. hub which is inherently concentric with the rod. This precise concentricity of all parts of the snap action mechanism is important because it makes for equality of load and movement as between theA several levers 22a to 22j-without which precision it would be impossible economically to manufacture in volume devices which would operate uniformly to open and close the valve at a predetermined temperature differential.

It is desirable and most economical but not indispensable that annulus 2| be mounted on a hub which, in turn. is mounted on and carried by the Invar rod, as per Figs; 1 to '7. In Fig. 8 we have shownan alternative structure which operates in the same way as that of Figs. 1 to '1, inclusive, but in which the snap-action annulus is supported independently of the Invar rod-being mounted loosely on a sleeve 29 which is centered in and supported by the body casting. Sleeve 29 serves only as a centering support for the annulus, and a separate plunger element 30, secured to the rod, carries the movable annular fulcrum corresponding to fulcrum 23h of Fig. 6. Plunger element 30 should be a close running t in the bore of sleeve 29 becauseotherwise the resultant possible eccentricty between the spider and the annulus may impair the accuracy of the device. Manifestly, the structure of Fig. 8 is somewhat more costly than that of Figs. 1 to '7, andit does notperform any better or dierently. It is, however, a considerable improvement over the prior art from the standpoint of manufacturing economy and represents a workable and commercially practicable embodiment of our invention.

Fig. 9 depicts another embodiment of our invention in the form of a snap-action thermo- 'static valve wherein the snap-action element is a complete disc instead of an annulus and wherein theimanual temperature regulating means does noit comprise a knob and disc at the front i' thedevice but, on the contrary. a lever situated toward the rear of the device.

InFig. 9, 3i is the body casting; 3 2 is' the expansible copper tube; 33 is the Invar rod; 34 is a hub member pinned to the end of the Invar rod and movable'therewith; 38 is a snapaction disc, cupped at the center in two steps to conform to the shape of the hub memberto provide a centering support for the disc. The disc is so formed as to provide a centering hub at 38a for a spider 38, similar to spider 22 previously described-and further formed to provide a shoulder at 35h which acts as the moving fulcrum forl spider 38, A plug 31 screwed into the body casting includes a stationary annular 4iulcrum 31a for spider" 38. When Invar rod 33 moves to the left, as viewed in Fig.

9, the spider levers will snap disc 38 and open the valve. A lever 38 securedI to rod 33 serves the same purpose as knob 8 and dial 4.. of the device oi Figs. l to 7. Lever 38 is manually operable to rotate rod 33. Suitable graduations and indices may be provided on the body casting to inform the householder as to the average temperature for which the device is set. The provision of a lever, such as lever 38, situated toward the rear of the device, is'old practice. It will be self-evident that temperature indices on the body casting to register with lever 38 would not be as easy to read as the markings on the dial 4 in the structure of Figs. l to'l; and that the purpose of lever 38 and its mode of operation would not be as clear to the average housewife as the purpose and mode of operation of knob 5 and dial 4; The fuel control valve and operating lever in Figs. 8 and 9 are identical to those in the structure of Figs. 1 to 7,

Fig. 10 illustrates/ a spider 40 which can be substituted for spider 22. Here the six resilient lever arms 48a to 40f, inclusive, are tied together by a peripheral rim 4i which serves the same purpose as the central web of spider" 22. We prefer spider 22 to that of Fig. 10 because the stamping die is more simple and less fragile.

Fig. 1l illustrates another snap-action mecha nism within the purview of our invention wherein the spideri has been omittedy and the essential amplification of the movements of the Invar rodis achieved by applying the forcecouple to the annulus in the manner of Spencer, U. S. Letters Patent No. 1,478,407. In this'structure the Invar rod is identified by reference numeral 42. A shouldered hub 43 pinned to the Invar rod serves to center and support the snap-action annulus 44 and also serves as anabutment or pusher member for the annulus and as one of the annular fulcrums through which the actuating force couple is applied to the annulus. A sleeve 45 slidably mounted on rod 42 has an `annular iulcrum 45a which bears against the to the annulus 44. amplification of movementsl y of the Invarrod is obtained in the snap-action annulus itself-as vin the Spencer device-and, ordinarily. it is unnecessary to provide forexternal amplication in order to snap the annulus in response to a very small longitudinal movement of the Invar rod. In an arrangement like that of Fig. 11 it is not usually necessary to provide a special yieldable element for the purpose of effecting snap action of the disc because the Invar rod and copper tube will vyield enough to take care of the very small follow through movement which must be given to hub 43 when the annulus starts its movement over dead center. We have, however, provided .a yieldable element in theshape of a coil spring 46 which will function totake ycare of the follow through movement, but which, primarily, is not provided for that purpose. The main function of the heavy spring 48 is to protect the snapaction annulus and other parts of the device from the violent force which otherwise would'be built up if the device were subjected to very low subzero temperatures. When such a condition occurs spring 48 yields and thereby diminishes the force applied to annulus 44. The snap-action mechanism of Fig. 1l ,can be substituted' for the snap-action mechanism of Figs. 1 to 7.

When knob 5 of the device oi' Figs. 1 to 7 or that of Fig. 8 is rotated clockwise, as viewed in Fig. 1, the left-hand thread at I3` causes rod II to advance to the left, as viewed in Figs. 2, 3, 6 and 8. This movement of the Invar rod results in snapping the annulus to the abnormal configuration of Fig. 3 and opening the fuel control valveif the valve does riot happen already to be open when the adjustment is undertaken. After the temperature-increasing adjustment has been made it is necessary for the copper tube 8 to expand to a correspondingly increased extent in order to permit annulus 2|` to snap back to its normal conilguration; and,' manifestly, a higher water temperature must be attained to effect the increased expansion of the copper tube. Conversely, a counterclockwise rotation of knob 5', as viewed in Fig. 1 causes the Invarv rod to move to the right, as viewed in Figs. 2; 3, 6 and 8 and, as a consequence, a smaller expansion of theA copper tube will cause the valve to close. This means that the maximum water temperature is decreased. In the device of Fig. 9 water temperature regulation is accomplished in the same way except that the Invar rod is rotatedl an annulus which can be snapped from the nor-.

mal form of Fig. 2 to the abnormal form of Fig.

` 3 and which will restore itself to the normal form when the pressure is released or reduced l"to a suitable extent. Whether or not a particular annulus will be self-restoring depends upon its dimensions and form and upon the material out `of which itis made. We cannot furnish any Aformula whereby to determine the design and proportions which `will produce a self-restoring and satisfactorily operative annulus under dii'- ferent xed conditions; but in order to complete our disclosurewe will specify the dimensions of the annulus of Figs. 1 to 7, which is being successfully employed in a temperature regulator of the design shown. The annulus is' made of .011 inch stainless spring steel sheet. Its outside diameter is inch. The central aperture is circular and of 1/2 inch diameter; and the oil'setl when the annulus isy in its normal form is between .040 inch and .050 inch.

We claim:

l. In a temperature-regulating device, thermosensitive means, a rod connected with 'said thermosensitlve means and movable axially by said means in response-to temperature changes, a hub member secured to said rod, a normally dished snap-action annulus mounted on said hub member; said annulus 'having an axial opening by which it is centered on said hub member, said hub member having Aa shoulder which bears against one face of saidannulus adjacently to said axial opening, yieldable means bearing against .the opposite face of said annulus and capable 4of exerting suilicient distorting/pressure on said annulus to cause said annulus to snap from its normal form to its abnormal form, said annulus being capable of restoring itself to its normal form when the distorting pressure is removed, and a valve operatively' connected with the peripheral portion of said annulus.

2. A temperature-regulating device in accordance with claim 1 wherein said annulus is of frustro-conical form.

3. In a temperature-regulating device, thermosensitive means, a rod connected with said thermosensitlve means and movable axially by said means in 'response to temperature changes, a hub member secured to said rod, a normally dished snap-action annulus mounted on said hub member, said annulus having an axial opening by which it is centered on said hub member, said hub member having a shoulder which bears against one face of said annulus adjacently to said axial opening, yieldable means bearing against the opposite face of said annulus and capable of exerting sumcient distorting pressure on said annulus to cause said annulus to snap from its normal form to its abnormal form, said annulus being capable of restoring itself to its normal form when the distorting pressure is removedfa valve, and a lever interconnecting said valve with the peripheral portion of said annulus.

4. A temperature-regulating device in accordance with claim 3, characterized in that said lever has a relatively short lever arm which engages the peripheral portion of the annulus, and a long'lever arm which is operatively connected with the valve, the arrangement being such that` van amplification of the movement of the periphery of the annulus is eilected by said lever and .transmitted thereby to said valve, thereby accomplishing a comparative increase in the extent.

of opening of said valve.

5. In a temperature-regulating device, a body casting having a fuel-passageway therethrough and a valfve interposed in said passageway for interrupting the ilow of fuel therethrough, said valve including a closure member and a valve seat, a spring. for closing said valve,` a thermosensitive element comprising a thermally expansible tube one end of which is connected to said f body casting, a rod co-axlal with said tube and said central opening, yieldable means bearing against the opposite face of said annulus and capable of exerting suiilcient distorting pressure on said annulus to cause said annulus to snap from its normal form kto its abnormal form,

thereby eil'ecting.an abrupt movement ofthe peripheral edge "of said annulus-axially of said rod, -and a lever-system for transmitting the abrupt movement, at least in one direction, of said peripheral edge to said valve for opening said valve, said lever system comprising a short lever arm, the free end of which engages said annulus near the periphery thereof.. and a long lever arm, the free end of which is operatively connected with said valve.

6. The combination, with a thermosensitive element of a rod operatively associated with said element and movable axially thereby in response to temperature changes, a hub member mounted on said rod and secured thereto, a frustro-conical annulus of spring sheet material having a comparatively large central opening by which it is centered on said hub member, said hub member vhaving a shoulder which engages one face of said annulus along the edge of said central Opening, a spider mounted on said rod and having a plurality of resilient radially extending arms which engage the opposite face of said annulus near the periphery thereof, said hub member having an annular fulcrum which engages one face of said Spiden and a sleeve mounted on said rod but not secured thereto, said sleeve having an annular fulcrum bearing against the opposite face of said spider, said last-mentioned annular fulcrum bearing against said "spider along a circumference of greater diameter than that of said first-mentioned annular fulcrum.

7. The combination with a thermosensitive element, of a rod operatively associated with said element and movable axially .thereby in response to temperature changes, a hub member mounted on said rod and secured thereto, a frustro-conical annulus of spring-sheet material having a comparatively large central opening by which it is centered on said hub member, said member having a shoulder which engages one face of said said means in response to temperature changea. f

a hub member secured to said rod; a normally dished snap-action annulus mounted on said hub member, said annulus having an axial opening by which it is centered on said hub member, saidhub member having a shoulder which bears against one face of said annulus adjacently to said axial opening, yieldable means bearing against the opposite face of said' annulus and capable of exerting suillcient distorting pressure on said annulus to cause said annulus to snap from its normal. form to its abnormal form, said annulus being capable of restoring itself to its normal form when the distorting pressure is removed, an element-to-be-actuated, and a lever interconnecting said element-to-be-actuated with the peripheral portion of said annulus.

9. The combination with a thermosensitive clement, of a rod operatively associated with said element and movable axially thereby in response to temperature changes, a dished snapaction over center device of spring material having a central opening through which said rod extends, said over center device being carried by" said rodI means defining a shoulder secured to said rod and movable therewith, said shoulder bearing against one face of said over center device adjacent the peripheral edge of said open- 1' ing, a plurality of radially extending resilient lever arms disposed concentrically about said rod and having their outer ends bearing against the opposite face of said over center device near the outer periphery thereof, and fulcrum structure bearing against each of said lever arms at points intermediate the ends thereof for exerting pressure through said lever arms against said over center device in opposition to said shoulder, said lever arms being sufficiently stiff to be capable,

conjointly, of transmitting force enough against said over center device to cause said device to snap from its normal form to its abnormal form, but suillciently lresilient to prevent, under ordinary conditions, such excessive force being ap- "5 plied to said device as would cause permanent deformation thereof.

10. The combination with a thermosensitive element, of a rod operatively associated with said element and movable axially thereby in response to temperature changes, aV dished snap-action over center device of spring material the center portion of which is so disposed as to be forcibly yacted upon by said rod for effecting an over center snap-action movement of said device in re- 3 sponse to lengthwise movement ofsaid rod in one direction, said device being capable of self-restorationwhen the force applied thereto by said rod is relieved, abutment means operative upon said device in'co-operation withsaid rod for ap- 40 plying, indirectly, a reactive force to said device in opposition to that applied by said rod, and a plurality of resilient lever arms disposed concentrically about and extending radially from the axial center of said device, said levers being l5 interposed between said abutment means and one face of said over center device, the outer end of each oi' said arms bearing against said face near the outer peripheral edge of said device, said lever arms, conjointly, being operative as a yieldbeing yieldable enough to prevent, under ordinary conditions, the application of enough force to said device to cause permanent deformation thereof.

11. A thermostatic snap-action mechanism comprising, in combination, a self-restoring on snap-action over center disc of spring material having a free peripheral edge, said disc being supported axially, a rod extending axially of said disc and concentric therewith, said rod being movable lengthwise thermostatically. a plurality 6.

of movement-amplifying levers situated adjacent said disc and bearing against the normally concave face of said disc near the peripheral edge thereof. said levers being operatively associated with said rod and so fulcrumed as to amplify the 7o lengthwise movements oi said rod and transmit said movements in amplified form to said disc for mapping said disc.

12. A thermostatic snap-action mechanism comprising, in combination, a self-restoring snapaction over center disc of spring material having a free peripheral edge, said disc being supported axially, a rod extending axially of said disc and concentric therewith, said rod being movable lengthwise thermostatically, a plurality of resilient movement-amplifying levers situated adjacent the normally concave face of said disc, said levers being disposed about the axialcenter of said disc and extending radially therefrom, the outer ends of said levers bearing against the normally concave face of said disc near the peripheral edge thereof, said levers being operatively associated with said rod and so fulcrumed as to amplify the lengthwise movements of said.rod and transmit said movements in amplified form to said disc for snapping said disc.

13. A thermostatic snap-action mechanism comprising, in combination, a self-restoring snapaction over center disc of spring materiald having a free peripheral edge, said disc being supported axially, abutment means bearing against the normally convex face of said disc at the center portion thereof. a spider situated adjacent the normally concave face of said disc and comprising a plurality of resilient movement-amplifying levers, said levers being disposed about the axial center of said disc and extending radially therefrom, the outer ends of said levers bearing against the normally concave face of said disc near the peripheral edge thereof, said levers being fulcrumed intermediate their ends and thermostaitic means for actuating said levers to snap said disc.

14. A thermostatic snap-action mechanism comprising, in combination, a self-restoring snapaction over center annulus of spring material having a free peripheral edge, a hub for centering and supporting said annulus axially, a rod extending axially through said hub and annulus,

a member attached to said rod and having an annulus fulcrum co-axial with said rod, structure including a second annular fulcrum, and a spider" interposed between saidl fulcrums and disposed adjacent the normally concave face of said disc, said spider comprising a plurality of resilient sheet metal levers disposed around the axial center of said annulus and extending radially from said axial center, the outer ends of said levers bearing against the normally concave face of said annulus near the peripheral edge thereof.

15. A thermostatic snap-action mechanism comprising, in combination, a self-restoring snapaction over center annulus of spring material having a free peripheral edge, a hub for centering and supporting said annulus axially, a rod extending axially through said hub and annulus, a plunger carried by said rod and slidably guided by said hub, said plunger having an annular fulcrum co'axial with said rod, structure including a second annular fulcrum, said fulcrums being spaced radially, and a spider interposed between said annular fulcrums and operative to be actuated thereby in response to longitudinal movements of said rod, said spider comprising a plurality of resilient sheet metal levers disposed around the axial center of said annulus and extending radially from said axial center, the outer ends of said levers bearing against the normally concave face of said annulus near the peripheral edge thereof. y

SIDNEY P. VAUGHN. WAYNE E. JENKINS. 

